JP3147841U - Super easy microtome - Google Patents

Abstract

[PROBLEMS] To carry out microscopic observation of various inspection materials (plant tissue, animal tissue, etc.), and without slicing various inspection materials, special techniques, equipment and facilities are not required, and in a short time. Thus, a microtome for preparing a microscope preparation (section) that can be observed as a result is provided. The microtome of the present invention is used for slicing a test material (plant tissue, animal tissue, etc.). The inspection material is sandwiched between a pair of supports, and the inspection material and the support are integrated. A test material held by a pair of supports is placed between a pair of L-shaped fixing plates. From the pair of L-shaped fixing plates, the test material is slightly extruded together with the support, and the test material is sliced using a blade with the extruded support and the test material sample. [Selection] Figure 1

Description

  The present invention relates to a microtome for slicing various test materials (samples such as plant tissue and animal tissue) to prepare a preparation (section) for microscopic observation.

  When observing various test materials (samples such as plant tissue and animal tissue) with an optical microscope, it is necessary to cut out as thin a slice as possible. In order to observe a sample such as a plant tissue and an animal tissue in detail, it is necessary to cut out at least a thickness of 20 μm or less.

  The preparation is obtained by processing the inspection material (sample) into a state in which it can be microscopically observed under the microscope observation. Usually, what was adjusted for observation of an optical microscope is called a preparation. In the basic preparation, a test material (sample) is pasted on a slide glass and sealed under a cover glass with an encapsulant. In the case of a biological sample, the test material (sample) is usually fixed so as not to impair the living state, cut into a few to several tens of microns in heat, pasted on a slide glass, and sealed after staining. To make. Temporary preparations are not preserved after microscopic examination and are often mounted with water or buffer. By using a mount solution that does not easily evaporate and sealing the edge of the cover glass with a manual or the like, it becomes possible to preserve it for several years. Therefore, what has been subjected to such a sealing process is called a semi-permanent preparation. In the case of an inspection material (sample) that is thick and cannot be prepared as it is, it is necessary to remove a sufficiently thin specimen by some means. The simplest method is to crush the test material (sample) (destructive method). If fine particles or fibers are used as structural units, observation is possible by gently crushing them and arranging the units on a plane. This annihilation method is used for observing the root tip meristem of onions used as science teaching materials in elementary and junior high schools.

  If the crushing method (extinction method) with a solid test material (sample) does not give sufficient results, cut the slices into slices. When a hand is cut with a razor blade or the like, it is called a manual section. This is done when the sample is of some size and stiffness and does not require a very thin section. When the sample is small and difficult to support, it is sandwiched between supports of moderate softness and cut with them. The easiest way to make sliced preparations is elderberry (scientific name: Sambucus sieboldiana, deciduous shrub of the honeysuckle family), kibushi (scientific name: Stachyurus praecox, genus deciduous shrub of the genus Kibushi family) and Yamabuki (scientific name: Kerria). japonica, a deciduous shrub of the genus Rosaceae. When slicing a hard plant such as camellia, the inspection material is rarely crushed even if it is sandwiched between pisses. However, since soft plant tissues and animal tissues have a high water content and are brittle, the tissue structure is destroyed at the stage of being sandwiched between pisses. Nowadays, natural elderberry, kibushi and yamabuki pis cannot be procured easily. When this support is used as a pis (medulla) and sliced manually using a razor blade, the thickness limit is about 50 μm, and the section size limit is about 2 mm × 8 mm. Conceivable.

  If a simple microtome is used, the section can be easily cut out. As a simple microtome, a method using a disposable syringe, a method using a long nut, a method using a hard vinyl chloride tube, a method using a micrometer head, etc. have already been devised. However, the problem with this simple microtome has not been completely solved. The problem is how to fix the pith (medulla) with different calibers stably, and what kind of blade to cut easily. When using a simple microtome, a pis (medulla) sandwiching the test sample is inserted into the inner tube of the microtome. If the diameter of the inner cylinder and the diameter of the pis (medulla) are completely coincident, a stable state is achieved and thin cutting is possible. However, since natural pith is not constant in thickness, a gap is generated between the inner cylinder and piss. In the state where there is a gap, the test sample and the pith are unstable, and it is difficult to slice. A simple microtome using a disposable syringe can be manufactured at a low cost and can cut out a section more easily than cutting a pith by hand. is there. In the case of a simple microtome using a micrometer head, there is no problem in adjusting the feeding amount of the inner cylinder, but since the micrometer head itself is expensive, a simple microtome using it is naturally a manufacturing cost. It becomes expensive. These methods are advantageous in that they are simple but quick, and there are few artifacts generated during processing. If a thin and precise section is required, or if it cannot be sliced by the above method due to the properties of the sample, the sample is fixed and embedded in a support, and then sliced using a microtome.

  A commercially available desktop hand microtome is an instrument that fixes a pith and feeds it little by little with a screw, and is expensive at about 60 to 70,000 yen. In the case of slicing using this desktop hand microtome, it is considered that the limit of the size of the section is about 10 mm × 15 mm. Since the minimum scale for sample feeding is 10 μm, the limit of thinness is considered to be about 10 to 20 mm. However, it is considered that the size of the section that can be sliced varies to a small value and the limit of the thickness varies to a thick value depending on the material, hardness, and the like of the sample. The hand microtome has only the function of feeding out the sample, and the slicing is performed with a razor blade held in the hand.

  The basic operation of the microtome is performed by feeding out a sample and sliding the blade in conjunction with it. The feeding mechanism, accuracy, and blade type vary depending on the application. The microtome for optical microscopes used to be a steel blade that has been sharpened with a grindstone and used repeatedly, but today, disposable blades have become the mainstream. Microtomes are classified into rotating and sliding types. The mechanism in which the blade is fixed and the sample moves repeatedly in the vertical direction in conjunction with the rotation of the handle is rotary, and the mechanism in which the sample is fixed and the blade moves in the front-rear direction is a sliding type. The rotary type is mainly used to make the slide, and the sliding type is mainly used to make a section of a large area. The sliding type is the mainstream in hospital examination rooms, and the rotary type is mainly used in universities, companies, and laboratories. A microtome is an instrument used to make a sample used for observation with a microscope into a very thin section. When a tissue is observed using an optical microscope in biology, medicine, mineralogy, etc., a preparation is usually prepared. When preparing this preparation, it is necessary to cut out the sample uniformly and thinly in order to ensure observation easily. In particular, when observing at a high magnification, the focus range is remarkably narrowed and the depth of field is shallow. A method such as manually cutting out a sample using a razor has a limit in accuracy, so a microtome is required. When a microtome is used, it becomes possible to cut out evenly in units of a micrometer. A rotary microtome and a sliding microtome are typical. The rotary microtome moves the sample while fixing the knife. The sample is moved up and down by changing the rotation of the handle to a reciprocating motion with a crank. The sample can be sliced into a certain thickness by feeding the sample little by little in conjunction with the movement of the sample, and it is used as a standard for the preparation of paraffin sections. The sliding microtome is designed to fix the sample to the delivery function and move the blade of the knife on the runway to cut it thinly. Conventionally, paraffin has been used for embedding a biological sample. However, it is necessary to completely dehydrate the fixed sample and to infiltrate the paraffin. Normally, when preparing a tissue specimen of an animal or the like, after formalin fixation, dehydration and paraffin embedding are performed, and a paraffin block is sliced with a microtome, and various stainings are performed. Although the tissue specimen produced by this regular method is easy to observe, it requires expensive equipment and requires about 3 days for the work process. On the other hand, when a frozen section is prepared with a cryostat, the time is greatly reduced, but an expensive instrument is required.

  When carrying out microscopic observation of plant tissue, animal tissue, etc., it is necessary to slice the inspection material (sample). Conventionally, various devices have been devised, but special techniques, equipment, facilities, etc. are not required, and preparations (sections) of plant tissue and animal tissue that can be observed as a result in a short time are prepared. Was very difficult.

  In view of the above problems, the object of the present invention is to cut various inspection materials (plant tissue, animal tissue, etc.) without special technology, equipment and facilities, and in a short time, as a result. Provided is a microtome for preparing an observable microscope preparation (section).

  In view of the above problems, the microtome of the present invention has the following configuration.

  The microtome of the present invention is used for slicing inspection materials (samples such as plant tissue and animal tissue) for observation with an optical microscope. If it is an animal tissue and does not have an appropriate hardness, fixation (for example, formalin fixation or microwave fixation) is necessary in advance. If it is plant tissue and has an appropriate hardness, fixation is not necessary. In the microtome of the present invention, the inspection material (sample) is sandwiched between a pair of supports (for example, two high-quality fired polystyrene having a thickness of about 5 mm), and the inspection material and the support are integrated. To do. Thereafter, the inspection material (sample) held by a pair of the supports is placed between a pair of L-shaped fixing plates (for example, two slide glasses or acrylic plates made vertical using wood or the like). Install. When slicing, the test material (sample) is slightly extruded together with the support from a pair of L-shaped fixing plates, and the extruded support and test material (sample) are bladed (for example, a cutter) The inspection material (sample) is sliced using a knife or a razor.

  In the microtome of the present invention, the inspection material (sample) is sandwiched between a pair of the supports, and the inspection material (sample) and the support are integrated. Then, the said inspection material (sample) hold | maintained with a pair of said support body is installed between a pair of L-shaped said fixed plates. When slicing, a pair of L-shaped fixed plates are held by a movable contraction body (for example, two large clips or a laundry clothespin). By holding the pair of L-shaped fixed plates by the movable contraction body, a stable state is obtained and slicing becomes easy.

  In the microtome of the present invention, the microtome is used to adjust the thickness of the section in the process of pushing out the pair of supports from the pair of L-shaped fixing plates. Two vinyl tapes or cellophane tapes or the like are affixed on the flat plate at regular intervals, and a pair of steps are installed on the flat plate. The sample and the fixing plate held by the support are placed on a pair of steps on the flat plate, and the inspection material (sample) held by the pair of support from a pair of L-shaped fixing plates Extrude slightly. The support and the inspection material (sample) slightly extruded from the fixed plate are sliced with a blade (for example, a cutter knife or a razor). The thickness of the section can be adjusted by changing the height of the step on the flat plate with the thickness and number of vinyl tapes or cellophane tapes.

  The present invention is a microscope that can be observed in a short time and in a short time without the need for special techniques, equipment, facilities, etc., in slicing various inspection materials (samples of plant tissue, animal tissue, etc.) A microtome for preparing a preparation (section) for observation can be provided.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is an overall configuration diagram of the present invention, and FIGS. 2 and 3 are cross-sectional views of the present invention, respectively.

  FIG. 1 is an overall configuration diagram of Embodiment 1 of the present invention, and shows a schematic structure when various test materials (samples such as plant tissues and animal tissues) are sliced.

  The microtome of the present invention is inexpensive and can be observed in a short time without special techniques, equipment and facilities when slicing various test materials (samples such as plant tissue and animal tissue). It is possible to prepare a preparation (section) for microscopic observation. In addition, it is a microtome that can realize light weight and downsizing.

  FIG. 2 is a cross-sectional view of a second embodiment of the present invention. A microtome for slicing an inspection material (sample) for observing with an optical microscope, and a pair of the supports (for example, two sheets of about 5 mm in thickness) for fixing the inspection material (sample) And a pair of L-shaped fixing plates (for example, two slide glasses or acrylic plates made vertically using wood or the like) for holding the support. The inspection material (sample) is held by a pair of the support bodies, and the inspection material (sample) and the pair of support bodies are installed between a pair of L-shaped fixing plates. When slicing the inspection material (sample), the inspection material (sample) held by the pair of support bodies is slightly extruded from a pair of L-shaped fixing plates, and the support body extruded and the The inspection material (sample) is sliced by cutting the sample with a blade such as a cutter knife or a razor.

  The microtome of the present invention is used for slicing inspection materials (samples such as plant tissue and animal tissue) for observation with an optical microscope. If it is an animal tissue and does not have an appropriate hardness, fixation (for example, formalin fixation or microwave fixation) is necessary in advance. If it is plant tissue and has an appropriate hardness, fixation is not necessary.

  The L-shaped fixing plate for holding the support is manufactured by sticking two slide glasses or an acrylic plate with double-sided tape or the like to two surfaces of a square material such as wood or plastic having a vertical surface. To do. Two L-shaped fixing plates are produced, and the two are used as one set.

  The support for fixing the inspection material (sample) is produced by cutting a foamed polystyrene into a thickness of about 5 mm, a length of about 40 mm, and a width of about 40 mm. Two of the supports are prepared and used as a set. The material of the support is selected according to the hardness of the inspection material (sample). For example, in the case of the relatively soft inspection material (sample), a soft foam polystyrene is used for the support, and in the case of the relatively hard inspection material (sample), a hard foam polystyrene is used for the support. Slicing is easy. When the test material is a hard plant tissue or the like, slicing is easy if a balsa material is used as the support. In the microtome of the present invention, since the inspection material (sample) and the support are sliced simultaneously, it is easier to slice the support using a material having the same hardness as the inspection material (sample). is there.

  In the microtome of the present invention, the inspection material (sample) is sandwiched between a pair of supports (for example, a foamed polystyrene having a thickness of about 5 mm), and the inspection material (sample) and the pair of supports are integrated. To do. Then, the said inspection material (sample) hold | maintained with a pair of said support body is installed between a pair of L-shaped said fixed plates. In this state, the inspection material (sample), the support and the fixing plate are not integrated. When slicing, it is held from the outer edges of the pair of L-shaped fixing plates using, for example, a plurality of large clips or movable contractors such as laundry clothespins. By holding the pair of L-shaped fixed plates by the movable contraction body, a stable state is obtained and slicing becomes easy.

  FIG. 3 is a cross-sectional view of Embodiment 3 of the present invention, and shows a schematic structure for adjusting the thickness of a slice when sliced with the microtome of the present invention.

  This is an instrument for easily adjusting the thickness of a slice when slicing with the microtome of the present invention. It is used to adjust the thickness of the section in the process of pushing out the pair of support members from the pair of L-shaped fixing plates. Two vinyl tapes or cellophane tapes or the like are pasted on the flat plate at a constant interval, and a pair of steps are set on the flat plate. Furthermore, when finely adjusting the step, a plurality of vinyl tapes and cellophane tapes are combined and pasted on the flat plate. The sample and the fixing plate held by the support are placed on a pair of steps on the flat plate, and the inspection material (sample) held by the pair of support from a pair of L-shaped fixing plates Extrude slightly. The inspection material (sample) is sliced by cutting the support and the inspection material (sample) slightly extruded from the fixed plate with a blade such as a cutter knife or a razor. By adjusting the height of the step with the thickness and number of vinyl tapes or cellophane tapes, the thickness of the section can be easily adjusted.

  As described above, according to the microtome of the present invention, it is possible to cut various inspection materials (samples such as plant tissue and animal tissue) inexpensively, without requiring special techniques, equipment and facilities, and in a short time. Thus, it is possible to produce a microscope observation preparation (section) that can be observed as a result.

FIG. 1 is an overall configuration diagram of a microtome according to the present invention, and shows a schematic structure when various inspection materials (plant tissue, animal tissue, etc.) are sliced. FIG. 2 is a sectional view of a microtome according to the present invention. FIG. 3 is a cross-sectional view of Embodiment 3 of the present invention, and shows a schematic structure for adjusting the thickness of a slice when sliced with the microtome of the present invention.

Explanation of symbols

1 L-shaped fixed plate (slide glass, acrylic plate, etc.)
2 Vertical materials such as wood or plastic with a vertical surface
4 Support (fired polystyrene with a thickness of about 5mm)
5 Inspection material (sample)
6 Movable contractors (large clips, laundry clothespins, etc.)
7 blades (cutter knife, razor, etc.)
8 Flat plate 9 High step (vinyl tape, multiple cellophane tapes, etc.)
10 Low step (cellophane tape, etc.)

Claims (3)

  A microtome for slicing a sample for observation with an optical microscope, a microtome having a pair of supports for fixing the sample and a pair of L-shaped fixing plates for holding the support The sample is held by a pair of the support members, the sample and the support member are installed between a pair of L-shaped fixing plates, and the thin plate is held by the support member from the fixing plate when the slice is cut. A microtome characterized by extruding a sample and slicing the sample by cutting the extruded support and the sample with a blade (knife or the like).   2. The microtome according to claim 1, wherein the pair of support bodies and the pair of L-shaped fixing plates are held by a movable contraction body.   A device for extruding the sample held by the support from the fixing plate used in the microtome according to claim 1, wherein a pair of steps are installed on a flat plate, and the sample and the fixing plate are held by the support Is placed on the pair of steps of the flat plate, and the sample held by the support is pushed out from the fixed plate.

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